High voltage direct current transmission and distribution system

ABSTRACT

A direct current to alternating current inverter sub-system is for a HVDC distribution system. The DC to AC inverter sub-system includes an enclosure and a DC to DC galvanically isolated buck converter having a DC input electrically connectable to a HVDC cable and a DC output. A DC to AC inverter includes a DC input electrically connected to the DC output of the DC to DC galvanically isolated buck converter and an AC output electrically connectable to an AC transmission line. The DC to AC inverter is mounted in an enclosure with the DC to DC galvanically isolated buck converter, in order that the DC output of the DC to DC galvanically isolated buck converter is directly electrically connected within the enclosure to the DC input of the DC to AC inverter.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of, and claims priority under 35 U.S.C.§120 from, U.S. patent application Ser. No. 13/901,770, filed May 24,2013, entitled “HIGH VOLTAGE DIRECT CURRENT TRANSMISSION ANDDISTRIBUTION SYSTEM”, the contents of which are incorporated herein byreference.

BACKGROUND

Field

The disclosed concept pertains generally to power distribution and, moreparticularly, to high voltage direct current transmission anddistribution systems, such as, for example, such systems for aboveground, below ground or subsea applications. The disclosed conceptfurther pertains to circuit interrupters for high voltage direct currentdistribution systems.

Background Information

Alternating current (AC) power distribution systems are well known.

High voltage, direct current (DC) power distribution systems have lessenergy losses and require less costly transmission cables thancorresponding AC distribution systems. In long transmission lines and,in particular, in ones that use cable, high voltage DC powertransmission may be the only feasible method of power transmissionbecause using AC will cause debilitating instability and excessivelosses.

When connecting a DC voltage source to a relatively long cabletransmission line when the cable capacitance is discharged, relativelylarge oscillatory currents occur which, in turn, generate relativelylarge voltage spikes along the cable length. These voltage spikes cancompromise the insulation of the cable itself as well as the insulationof any device electrically connected thereto.

Furthermore, the relatively large oscillatory currents can causenuisance tripping of protection devices of the transmission line.

There is room for improvement in high voltage direct currenttransmission and distribution systems specifically regarding, forexample, the cable charging process when the transmission line isenergized.

There is also room for improvement in circuit interrupters for suchsystems.

SUMMARY

These needs and others are met by embodiments of the disclosed conceptin which a direct current to alternating current voltage source inverteris mounted in an enclosure with a corresponding galvanically isolateddirect current to direct current converter, in order that a directcurrent output of the galvanically isolated direct current to directcurrent converter is directly electrically connected within theenclosure to the direct current input of the direct current toalternating current voltage source inverter.

These needs and others are also met by embodiments of the disclosedconcept in which a circuit interrupter for a power circuit of a highvoltage direct current distribution system comprises a controllercooperating with the series combination of a solid-state switch and anelectromechanical isolation switch to open, close and trip open thepower circuit, the controller being structured to repetitively turn onand turn off the solid-state switch when the electromechanical isolationswitch is closed, in order to control charging of the power circuit fromzero volts to a high direct current voltage.

In accordance with one aspect of the disclosed concept, a high voltagedirect current transmission and distribution system comprises: analternating current to direct current converter including an alternatingcurrent input and a direct current output; a first high voltage directcurrent cable including a first end electrically connected to the directcurrent output of the alternating current to direct current converterand an opposite second end; and a distribution system comprising: anumber of high voltage direct current circuit breakers, each of thenumber of high voltage direct current circuit breakers including a firstportion electrically connected to the opposite second end of the firsthigh voltage direct current cable and a second portion; a number ofsecond high voltage direct current cables, each of the number of secondhigh voltage direct current cables including a first end electricallyconnected to the second portion of a corresponding one of the number ofhigh voltage direct current circuit breakers and an opposite second end;a number of galvanically isolated direct current to direct currentconverters, each of the number of galvanically isolated direct currentto direct current converters including a direct current inputelectrically connected to the opposite second end of a corresponding oneof the number of second high voltage direct current cables and a directcurrent output; a number of direct current to alternating currentvoltage source inverters, each of the number of direct current toalternating current voltage source inverters including a direct currentinput electrically connected to the direct current output of acorresponding one of the number of galvanically isolated direct currentto direct current converters and an alternating current output; a numberof alternating current transmission lines, each of the number ofalternating current transmission lines including a first endelectrically connected to the alternating current output of acorresponding one of the number of direct current to alternating currentvoltage source inverters and an opposite second end; and a number ofalternating current loads, each of the number of alternating currentloads electrically connected to the opposite second end of acorresponding one of the number of alternating current transmissionlines, wherein each of the number of direct current to alternatingcurrent voltage source inverters is mounted in an enclosure with acorresponding one of the number of galvanically isolated direct currentto direct current converters, in order that the direct current output ofthe last such corresponding one of the number of galvanically isolateddirect current to direct current converters is directly electricallyconnected within the enclosure to the direct current input of acorresponding one of the number of direct current to alternating currentvoltage source inverters.

As another aspect of the disclosed concept, a direct current toalternating current inverter sub-system is for a high voltage directcurrent distribution system. The direct current to alternating currentinverter sub-system comprises: an enclosure; a direct current to directcurrent galvanically isolated buck converter including a direct currentinput electrically connectable to a high voltage direct current cableand a direct current output; and a direct current to alternating currentvoltage source inverter including a direct current input electricallyconnected to the direct current output of the direct current to directcurrent galvanically isolated buck converter and an alternating currentoutput electrically connectable to an alternating current transmissionline, wherein the direct current to alternating current voltage sourceinverter is mounted in the enclosure with the direct current to directcurrent galvanically isolated buck converter, in order that the directcurrent output of the direct current to direct current galvanicallyisolated buck converter is directly electrically connected within theenclosure to the direct current input of the direct current toalternating current voltage source inverter.

As another aspect of the disclosed concept, a circuit interrupter for apower circuit of a high voltage direct current distribution systemcomprises: a first terminal; a second terminal; an electromechanicalisolation switch; a solid-state switch electrically connected in serieswith the electromechanical isolation switch between the first and secondterminals; and a controller cooperating with the solid-state switch andthe electromechanical isolation switch to open, close and trip open thepower circuit, the controller being structured to repetitively turn onand turn off the solid-state switch when the electromechanical isolationswitch is closed, in order to control charging of the power circuit fromzero volts to a high direct current voltage.

BRIEF DESCRIPTION OF THE DRAWINGS

A full understanding of the disclosed concept can be gained from thefollowing description of the preferred embodiments when read inconjunction with the accompanying drawings in which:

FIG. 1 is a block diagram of an example high voltage direct current(HVDC) transmission and distribution system in accordance withembodiments of the disclosed concept.

FIG. 2 is a block diagram showing a plurality of alternating current todirect current (AC/DC) converters electrically connected in series foruse with the HVDC transmission and distribution system of FIG. 1.

FIG. 3 is a block diagram showing a plurality of AC/DC converterselectrically connected in parallel for use with the HVDC transmissionand distribution system of FIG. 1.

FIG. 4 is a block diagram showing a plurality of AC/DC converterselectrically connected in parallel and series for use with the HVDCtransmission and distribution system of FIG. 1.

FIG. 5 is a block diagram of another example HVDC transmission anddistribution system for subsea applications in accordance with anotherembodiment of the disclosed concept.

FIGS. 6A-6B form a block diagram of another example HVDC transmissionand distribution system for subsea applications in accordance withanother embodiment of the disclosed concept.

FIG. 7 is a block diagram of an HVDC transmission and distributionsystem for subsea applications.

FIG. 8 is a block diagram of another example HVDC transmission anddistribution system for subsea applications in accordance with anotherembodiment of the disclosed concept.

FIGS. 9-12 are block diagrams of modular circuit breaker distributionmechanisms for use with the HVDC transmission and distribution system ofFIG. 1.

FIGS. 13-15 are plots of DC bus voltage, a number of generated voltagepulses, a number of generated current pulses, and a number of gatecommand signals for different portions of a pre-charge cycle of a HVDCcircuit breaker in accordance with another embodiment of the disclosedconcept.

FIG. 16 is a block diagram in schematic form of a HVDC circuit breakerin accordance with another embodiment of the disclosed concept.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

As employed herein, the term “number” shall mean one or an integergreater than one (i.e., a plurality).

As employed herein, the statement that two or more parts are “connected”or “coupled” together shall mean that the parts are joined togethereither directly or joined through one or more intermediate parts.

As employed herein, the term “low voltage” shall mean any alternatingcurrent voltage that is less than about 1000 V_(RMS) (i.e., a lowalternating current voltage), or any direct current voltage that is lessthan about 1500 VDC (i.e., a low direct current voltage).

As employed herein, the term “medium voltage” shall mean any alternatingcurrent voltage greater than a low alternating current voltage and inthe range from about 1 kV_(RMS) to about 38 kV_(RMS) (i.e., a mediumalternating current voltage), or any direct current voltage greater thana low direct current voltage and in the range from about 1500 VDC toabout 50 kVDC (i.e., a medium direct current voltage).

As employed herein, the term “high voltage” shall mean any suitablealternating current voltage greater than a medium alternating currentvoltage (i.e., a high alternating current voltage), or any suitabledirect current voltage greater than a medium direct current voltage(i.e., a high direct current voltage). A high direct current voltage isalso equivalently referred to as high voltage direct current (HVDC)herein.

Referring to FIG. 1, a high voltage direct current (HVDC) transmissionand distribution system 2 includes an alternating current to directcurrent (AC/DC) converter 4, an HVDC cable 6, and a distribution system7 including a number of HVDC circuit breakers 8 for a number of branchloads, a number of HVDC transmission lines 10, a number of galvanicallyisolated direct current to direct current (DC/DC) converters 12, anumber of voltage source inverters 14, a number of three-phasetransmission lines 16, and a number of AC loads, such as a number of ACmotors 18.

In one example embodiment, the AC/DC converter 4 and a portion of theHVDC cable 6 are above the surface of the sea or above ground, and theremaining portion and the rest of the system 2 are subsea or belowground.

In another example embodiment, all of the system 2 is subsea or belowground.

The AC/DC converter 4 includes an AC input 4A and a DC output 4B. TheHVDC cable 6 includes a first end 6A electrically connected to the DCoutput 4B of the AC/DC converter 4 and an opposite second end 6B. Eachof the number of HVDC circuit breakers 8 includes a first portion 8Aelectrically connected to the opposite second end 6B of the HVDC cable 6and a second portion 8B. Each of the number of HVDC cables 10 includes afirst end 10A electrically connected to the second portion 8B of acorresponding one of the number of HVDC circuit breakers 8 and anopposite second end 10B. The number of DC/DC converters 12 aregalvanically isolated to avoid ground currents in relatively long HVDCcables, such as 10, and to permit the grounding of one of the phases ofthe DC to AC output 14B. Each of the number of galvanically isolatedDC/DC converters 12 includes a DC input 12A electrically connected tothe opposite second end 10B of a corresponding one of the number of HVDCcables 10 and the DC output 12B. Each of the number of DC/AC voltagesource inverters 14 includes a DC input 14A electrically connected tothe DC output 12B of a corresponding one of the number of galvanicallyisolated DC/DC converters 12 and an AC output 14B. Each of the number ofAC transmission lines 16 includes a first end 16A electrically connectedto the AC output 14B of a corresponding one of the number of DC/ACvoltage source inverters 14 and an opposite second end 16B. Each of thenumber of AC loads 18 is electrically connected to the opposite secondend 16B of a corresponding one of the number of AC transmission lines16. Each of the number of DC/AC voltage source inverters 14 is mountedin an enclosure 20 with a corresponding one of the number ofgalvanically isolated DC/DC converters 12, in order that the DC output12B thereof is directly electrically connected within the enclosure 20to the DC input 14A of a corresponding one of the number of DC/ACvoltage source inverters 14.

Example 1

The AC/DC converter 4 can be installed on or above the surface of thesea or underwater (e.g., subsea) and is structured to ramp the DCvoltage of the DC output 4B at a limited rate in order to avoid highvoltage transients in the transmission line of the HVDC cable 6 duringits energization. In the case of underwater installation, there is anisolation transformer (not shown) on a platform (not shown) and amulti-pulse transformer and converter (not shown) underwater. Thisconfiguration minimizes the ground current at the source.

The HVDC circuit breaker 8, the HVDC cable 10, the galvanically isolatedDC/DC converter 12, the DC/AC voltage source inverter 14, the enclosure20, the AC transmission line 16, and the AC load 18 are either subsea orbelow ground.

As a non-limiting example, the typical output voltage of the AC/DCconverter 4 is +/−5 kV to +/−30 kV and the AC/DC converter 4 can beconnected in series (FIG. 2), in parallel (FIG. 3) or in series and inparallel (FIG. 4), in order to scale the output power and/or voltage ofthe DC output 4B. The AC/DC converter 4 increases the HVDC at a ratethat will prevent any high voltage transients from forming during thetransmission line energization. Being an active converter, the AC/DCconverter 4 is capable of shutting down in case of a short circuit faultin the HVDC cable 6 or in the first input portion 8A of the HVDC circuitbreaker 8. Hence, a fault current generated due to a short circuit inthe transmission line of the HVDC cable 6 or in the HVDC circuit breakerfirst input portion 8A is contained by the AC/DC converter 4. If thereis such a short circuit, then the AC/DC converter power semiconductorswitches (not shown) are turned off to prevent excessive energy to flowin the downstream power circuit.

The AC electrical energy from a generator (not shown) is transformedinto DC electrical energy using the AC/DC converter 4, which can beimplemented using diodes or active semiconductor switches (not shown).Normally, a multi-pulse AC input 4A is employed in order to reduce theharmonic distortion footprint in the utility. Whether it uses the diodesor the active semiconductor switches, such as IGBTs, the AC/DC converter4 can have its DC output voltage slowly climb from zero to its ratedvalue (e.g., without limitation, 60 kVDC), although the methods used foreach type to achieve the slow output voltage climb are very distinct.The speed of the voltage climb affects the number of frequencycomponents applied to the transmission line of the HVDC cable 6. Thefaster the voltage climb is, the higher its frequency components. Highfrequency voltage content will cause the transmission line reactivecomponents to generate voltage transients that normally reach twice theapplied voltage (e.g., in the example of a 60 kVDC transmission voltage,the voltage spike generated by a fast voltage climb is about 120 kVDC).This will play havoc with the life of the components in the transmissionlines as well as over stress the cable insulation. To avoid this highvoltage transient, the disclosed concept reduces the AC/DC converteroutput DC voltage climb from zero to rated value. This DC voltage climbrate can be adjusted to the cable type and transmission line length ifthe fastest possible voltage climb is desired or to a predeterminedlonger rate that will cover any cable type and length.

Preferably, the AC/DC converter 4 is an active converter structured toshut down responsive to a short circuit condition operatively associatedwith the HVDC cable 6 and/or the circuit breaker 8, and structured toramp the DC voltage at the DC output 4B thereof at a predetermined rate(e.g., without limitation, 10 kVdc per second for distances up to 100km; 10 kVdc per two seconds for distances from 100 km to 200 km; 10 kVdcper three seconds for distances greater than 200 km) from zero volts toa suitable HVDC. The same rates are applicable for the HVDC circuitbreaker 8.

Example 2

The HVDC cable 6 employs bipolar transmission, and can be partiallyabove ground and partially below ground, partially above sea andpartially subsea, entirely subsea, or entirely below ground. Forexample, FIG. 5 shows another system 2′ in which the HVDC cable 6′ ispartially above sea and partially subsea. No unipolar transmission isallowed in subsea or below ground applications due to galvanic corrosionof components of the enclosures involved.

Example 3

The HVDC circuit breaker 8 includes a cable pre-charge function toprevent high voltage transients in the transmission line of the HVDCcable 10. The HVDC circuit breaker 8 protects a number of branchcircuits (e.g., FIG. 5 shows a plurality of branch circuits of pluralHVDC cables 10) derived off of the main HVDC transmission line of HVDCcable 6′, and pulse width modulates the output 8B to charge thedownstream load side transmission line of the HVDC cable 10 to preventhigh voltage transients due to cable length. A fault current generateddue to a short circuit in the transmission line of the HVDC cable 10 orthe input 12A of the galvanically isolated DC/DC buck converter 12 willbe contained and isolated by the HVDC circuit breaker 8. As a result,the DC circuit breaker solid-state switches (e.g., 26 of FIG. 16) areturned off to protect the downstream power circuit from excessiveenergy.

The transmission line of the HVDC cable 10 contains resistive 10R,inductive 10L and capacitive 10C components (FIG. 16). The impedancevalues of these components are proportional to the cable length. When avoltage pulse is applied to the transmission line, the cable resistiveand inductive components limit the current magnitude and its rate ofchange while its capacitive component stores the electric chargetransferred by the voltage pulse and defines a voltage magnitude acrossthe cable terminals 10T (FIG. 16). For a given cable length, themagnitude of the current and how quickly it climbs from zero to itsrated value is defined by its resistance and inductance, and the amountof voltage across the cable terminals 10T is defined by the cablecapacitance.

When the voltage pulse is first applied, the current in the HVDC cable10 climbs from zero to a maximum value. The rate of the current climb islimited by the cable inductance. If the voltage pulse is long enough,such that the current will reach its maximum value, this maximum valueis defined by the cable resistance. As this current flows, in time, itdefines an electric charge that is accumulated in the cable capacitanceand is reflected in the cable terminals 10T with a voltage magnitude.

By assuming a maximum cable length and, thus, a maximum resistance,inductance and capacitance, a minimum voltage increase can be calculatedacross the cable terminals 10T when a given voltage pulse is applied.This means that with a given voltage pulse width, a minimum voltageshould appear at the cable terminals 10T. If the voltage does not appearor is smaller than the calculated value, it means that there is a shortcircuit in the transmission line or at the load input.

It also means that a fault in the system 2 can be detected withoutallowing hundreds or thousands of amperes to flow in the transmissionline of the HVDC cable 10 before the fault is detected. This is called alook ahead function (e.g., function 22 of FIGS. 13-16), which looks forthe fault before fully energizing the transmission line. The rate ofchange of the current (di/dt) is defined by the cable inductance (L):di/dt=V/L

The steady state current magnitude (i) is defined by the cableresistance (R):i=V/R

The voltage (V) produced by the voltage pulse is defined by the cablecapacitance (C) and the current that is defined by the cable resistanceand inductance:V=i*t/Cwherein:

i*t is calculated from the double time integral of the di/dt=V/L plusthe time integral of the current, i=V/R, after the current reaches therated value defined by R and for the rest of the duration of the voltagepulse.

Example 4

Referring to FIGS. 13-16, the hybrid HVDC circuit breaker 8 providesboth a short circuit detection, look ahead function 22 and a cablepre-charge function 24. The circuit breaker 8 includes a solid-stateswitch 26 in series with an electromechanical switch 28. Theelectromechanical switch 28 is employed solely to galvanically isolatethe upstream primary circuit 27 from the downstream secondary circuit 29being switched on or off solely when no electric current is flowingthrough it, since the solid-state switch 26 can have leakage currentflowing through its semiconductor junction when it is turned off. Theadvantage of using solid-state switches (e.g., without limitation, IGBT;IGCT), such as 26, is that they can switch on and off much faster thanelectromechanical switches, such as 28. For example and withoutlimitation, a high voltage IGBT can turn on or off within fivemicroseconds, while an electromechanical switch can take dozens ofmilliseconds to do the same.

The circuit breaker 8 includes an inductor 30 in series with thesolid-state switch 26 and the electromechanical switch 28 to limit therate of change of the current. Utilizing the switching speed of thesolid-state switch 26 and the inductor 30, a relatively simple buteffective control strategy is employed to detect a short circuit or arelatively low insulation value in the DC power circuit underprotection, such as the example load 29.

Cable transmission lines exhibit an impedance which is composed ofinductive, capacitive and resistive components. If the load end isdisconnected or the load equipment is turned off, when the circuitbreaker 8 is turned on, the DC power source at 27 has to first chargethe capacitance of the transmission line of the HVDC cable 10 to reachthe source voltage level. The differential equation that defines thevoltage across the transmission line capacitance as a function of theinjected DC current is shown in Equation 1.Cc*[dV/dt]=i   (Eq. 1)wherein:

Cc is the cable capacitance which increases linearly with cable lengthas a function of its distributed capacitive components 10C;

dV/dt is the derivative of the voltage across the cable positive andnegative terminals 10T; and

i is the current in the HVDC cable 10.

This means that a DC voltage step increase at the cable terminals 10Tcan be attained by injecting a current, i, during a time t, as is shownby Equation 2.dV=[i*dt]/Cc   (Eq. 2)When the solid-state switch 26 is turned on and off, it generates acurrent impulse via the inductor 30. For the bipolar transmission line,there are two solid-state switches 26 and there are two inductors 30 asshown in FIG. 16. The current impulse has a duration which is determinedby how long the solid-state switch 26 was kept turned on (e.g., i*dt ofEquation 2). For a given cable capacitance Cc, the voltage step dV isachieved if there are no leakages due to insulation degradation or dueto a short circuit between the positive and negative cable terminals10T.

If the cable capacitance Cc is known, then the voltage step dV can bedetermined by turning the solid-state switch 26 on and then off by aknown amount of time using Equation 2.

If the cable capacitance Cc is not known, then the current impulseamplitude can be controlled through the inductors 30 by turning thesolid-state switches 26 on and then measuring and monitoring the currentamplitude by a controller 32 using current sensor 34. When the currentamplitude reaches a predetermined value, which should be equal to orless than the solid-state switch maximum current capability, then thecontroller 32 turns off the solid-state switches 26. The di/dt value islimited by the inductance of the inductors 30 (e.g., L1 and L2) as shownby Equation 3.di/dt=V/[L1+L2]   (Eq. 3)

If there is no short circuit between the positive and the negative cableterminals 10T, then after the current impulse above, there will be avoltage step developed in the HVDC cable 10. This voltage step is thenmeasured and monitored by the controller 32 using voltage sensor 36. Ifthe voltage is steady, then its value corresponds to the unknown cablecapacitance Cc. If a confirmation is needed, then a second currentimpulse can be injected in the same manner as was described above andthe resulting voltage step should be twice as large as the first voltagestep.

The above approach can also be used for the known cable capacitancecase.

If the monitored voltage step starts to decay within a few seconds, asdetected by the controller 32, then this means that there is a currentleakage due to an insulation degradation somewhere in the downstreampower circuit (e.g., in the HVDC cable 10 or any downstream load such asthe DC/DC converter 12).

The disclosed concept uses the controller 32 with the above capabilitiesto generate the current impulse, limit the current amplitude, andmeasure and monitor the voltage step as a consequence of the currentimpulse. The measurement of current and voltage can be achieved usingany suitable current and voltage sensors, such as 34,36.

By verifying that the voltage step is present and that it does notchange within a couple of seconds, the controller 32 infers that thecable insulation is healthy and that no short circuit is present. Thisis the look ahead function 22.

The electromechanical isolation switch 28 is in series with thesolid-state switch 26, such as for example and without limitation, apower semiconductor switch. The solid-state switch 26 controls andprotects against overload and fault currents while the electromechanicalswitch 28 is used to isolate the downstream protected branch circuit 29from the upstream power circuit 27 or mains. The electromechanicalswitch 28 opens and closes at no load. The series combination of theswitches 26,28 is electrically connected between first input portion 8Aand the second output portion 8B of the HVDC circuit breaker 8. Whenboth of the switches 26,28 are closed, the second portion 8B charges thedownstream HVDC cable 10 to or toward a HVDC.

The controller 32 forms a modulation element structured to repetitivelyturn on and turn off the solid-state switch 26 when theelectromechanical isolation switch 28 is closed, in order to controlcharging of the downstream HVDC cable 10 from zero volts to a HVDC fromthe first input portion 8A of the HVDC circuit breaker 8. Thismodulation element ramps a duty cycle of the solid-state switch 26 beingon from zero to one hundred percent, as will be described.

The controller 32 also provides a trip mechanism structured to detect afault downstream of the second output portion 8B of the HVDC circuitbreaker 8 responsive to a failure to charge the downstream HVDC cable10. As will be described, the trip mechanism applies a predeterminedcurrent pulse and detects a corresponding predetermined voltage increaseof a voltage of the downstream HVDC cable 10. The failure to charge canbe caused by a short circuit or an insulation failure of the downstreamHVDC cable 10.

As was indicated above, the circuit breaker 8 also includes the cablepre-charge function 24. To resolve the problems of nuisance tripping,relatively large oscillatory currents, and relatively large voltagespikes along the cable length when connecting a DC voltage source to arelatively long cable transmission line, the disclosed hybrid DC circuitbreaker 8 can be used to charge the cable capacitance Cc by utilizingthe relatively fast switching capability of the solid-state switches 26and the current limiting characteristic of the inductors 30.

After the controller 34 verifies that there is no short circuit and nocable insulation degradation, the controller 34 employs further currentimpulses to continue to charge the cable capacitance Cc, such as formedby the distributed capacitance components 10C. Then, after thecontroller 34 detects that the HVDC cable 10 is fully charged, thesolid-state switches 26 will remain turned on.

A relatively longer HVDC cable 10 will take relatively more currentimpulses and will take a relatively longer time to charge to the ratedsource DC voltage with the solid-state switches 26.

In one embodiment, the controller 32 predefines the current impulsefrequency and duty cycle, and then adjusts them by the thermal capacityof the hybrid circuit breaker 8 and by the solid-state switch maximumcurrent capability. In other words, the current impulse amplitude shouldbe equal to or smaller than the solid-state switch maximum current, andthe frequency of the impulses should not be so high that it will causethe solid-state switches 26 to overheat.

In FIG. 16, the voltage source 27 provides a relatively constant DCvoltage amplitude to the HVDC cable 10 and to the downstream load 29 viathe hybrid circuit breaker 8 as long as its output current capability isnot exceeded.

The disclosed concept can be employed for both unipolar and bipolar DCpower transmission even though for subsea or underground applicationsthe system should be bipolar to avoid galvanic corrosion effects whenusing the ground or the water as the return path for the electric DCcurrent. Unipolar is the transmission mode where the earth (or seawater) is used as the return path. In this case, only one pole istransmitted in an isolated cable. The return path is usually a buriedgraphite rod (not shown) on both ends of the transmission line coupledto a cable (not shown) that is then electrically connected to theequipment, such as 29. The bipolar transmission mode, shown in FIG. 16,uses two conductor cables 38,40, one for the positive pole and one forthe negative pole.

Every DC current impulse from the HVDC circuit breaker 8 adds to thecable voltage by accumulating electric charge in the cable capacitanceCc (Equation 2), but the impulse duration is short enough to prevent thecurrent from reaching an amplitude that will cause high voltagetransients. The current amplitude is advantageously limited by: (1) theimpulse duration (which is controlled by the controller 32); (2) theHVDC bus voltage amplitude; and (3) the inductance of the inductors 30(e.g., reactors).

The cable capacitance Cc varies linearly with the cable length and,thus, as the cable length increases, the cable capacitance Cc increasesproportional to the length increase. For a given current impulse(amplitude and time), the voltage across the cable terminals 10Tdecreases inversely proportional to the cable length increase.

This means that for a particular current impulse pattern (if fixed bythe controller 32), relatively more impulses are needed to charge theHVDC cable 10 to its desired or rated voltage as the cable lengthincreases. On the other hand, if the cable capacitance Cc is preloaded(e.g., without limitation, manually) to the controller 32, then it canadjust the current impulse to keep the pre-charge time the same. Thiscan also be achieved automatically by applying a predetermined currentimpulse and expecting an ideal voltage step as a consequence. If themeasured voltage is much lower than expected and it does not decayrapidly within a couple of seconds, then this means that the cablecapacitance Cc is relatively higher than expected. Otherwise, if themeasured voltage is much higher than expected as a consequence of thepredetermined current impulse, then this means that the cablecapacitance Cc is relatively lower than expected. In either case, thecontroller 32 can suitably adjust the current impulse to achieve theideal or desired cable charging time.

FIG. 13 shows the first pulse 42 of a pre-charge cycle 43 of thepre-charge function 24, which is also employed for the short circuitdetection, look ahead function 22 of FIG. 16. The desired DC bus voltagein this example is 60 kVDC. The first plot 44 shows the DC bus voltageafter the circuit breaker 8 switches at the cable input 10A. The examplevoltage reached after the first pulse 42 of the second plot 46 is 2.6kVDC. Otherwise, if the cable insulation is compromised, then thisvoltage will decrease rapidly. The second plot 46 shows the voltagepulse 42 generated when the circuit breaker solid-state switches 26 areturned on and then off. The example voltage pulse amplitude is 60 kVDC.The third plot 48 shows the current pulse 49 generated by the voltagepulse 42 and through the inductors 30. The example current pulseamplitude of 200 A is limited by the controller 32. The fourth plot 50shows the circuit breaker solid-state switches 26 gate command signal 52from the controller 32.

FIG. 14 shows the first fifty example pulses 54 of the pre-charge cycle43. Again, the DC bus voltage before the circuit breaker 8 switches inthis example is 60 kVDC. The first plot 56 shows the DC bus voltageafter the circuit breaker 8 switches at the cable input 10A. The examplevoltage reached after the first fifty example pulses 54 is 9 kVDC. Thesecond plot 58 shows the voltage pulses 54 generated when the circuitbreaker solid-state switches 26 are turned on and then off. The examplevoltage pulse amplitude is 60 kVDC. The third plot 60 shows the currentpulses 61 generated by the voltage pulses 54 and through the inductors30. The example current pulse amplitude of 200 A is limited by thecontroller 32. The fourth plot 62 shows the circuit breaker solid-stateswitches 26 gate command signals 52 from the controller 32.

FIG. 15 shows the full pre-charge cycle 43. Again, the DC bus voltagebefore the circuit breaker 8 switches in this example is 60 kVDC. Thefirst plot 64 shows the DC bus voltage after the circuit breaker 8switches at the cable input 10A. The voltage reached after thepre-charge cycle is 60 kVDC. The second plot 66 shows the voltage pulses54 generated when the circuit breaker solid-state switches 26 are turnedon and then off. The voltage pulse amplitude is 60 kVDC. The third plot68 shows the current pulses 69 generated by the voltage pulses 54 andthrough the inductors 30. The current pulse amplitude of 200 A islimited by the controller 32. The fourth plot 70 shows the circuitbreaker solid-state switches 26 gate command signal 52 from thecontroller 32. The command signal 52 stays high or turned-on fully at 71after the pre-charge cycle 43 is complete.

For the pre-charge function to work on a relatively long cable, theinductors 30 of FIG. 16 are not needed per se because the cableinductance will limit the di/dt. However, the inductors 30 are paramountduring a short-circuit (e.g., without limitation, directly right at theoutput 8B of the HVDC circuit breaker 8 in which case no cableinductance will limit the di/dt).

The cable pre-charge function 24 of the HVDC circuit breaker 8 preventshigh voltage transients in the HVDC transmission line of the HVDC cable10. The DC energy from the output 4B of the AC/DC converter 4 istransmitted to the HVDC circuit breaker 8 via the HVDC cable 6 (e.g.,without limitation, which can be dozens of miles long). The voltagetransient in this segment while it is energized is mitigated by therelatively slow climb of the AC/DC converter output voltage. Thispotential arrives at the input 8A of the HVDC circuit breaker 8 whoseoutput 8B feeds the HVDC cable 10 that feeds the correspondinggalvanically isolated DC/DC converter 12, which powers the correspondingDC/AC voltage source inverter 14.

To avoid the same issue described above in connection with the AC/DCconverter 4 ramping the DC voltage at a limited rate as to avoid highvoltage transients in the transmission line of the HVDC cable 6, theoutput 8B of the HVDC circuit breaker 8 is not switched on normally.Instead, the HVDC circuit breaker solid-state switches 26 are commandedon and off at relatively very short time segments. The solid-stateswitches 26 intended for the use in 60 kVDC circuit breakers can beswitched on or off within a few microseconds. This feature allows forthe HVDC circuit breaker output 8B to be modulated to permit acontrolled charging of the cable capacitance Cc and consequently a slowclimb of the cable voltage to avoid the two times voltage transient.Moreover, with this feature, the HVDC circuit breaker 8 can also detecta fault in the transmission line of the HVDC cable 10 or at the input12A of the DC/DC converter 12 by turning on and off. Therefore, thepre-charge and the look ahead functions are operating simultaneously.

As one non-limiting example, the controller 32 limits the current to 200A or less when the 60 kVdc voltage is switched on and off, and thecurrent derivative is limited by the inductors 30 in series with bothpositive and negative cables. When the HVDC cable 10 is fullydischarged, its voltage Vc is equal to zero volts between the positiveand negative cables, and the first pulse will have a current derivativedefined by:di/dt=(60 kVdc−Vc)/Lwherein:

L is the sum of the inductances of both inductors 30 (L1 and L2);

Vc is the instantaneous cable voltage;

di is 200 A;

dt is the time required to reach di; and

60 kVdc is the input voltage from the AC/DC converter 4.

This means that:dt=(di*L)/(60 kVdc−Vc)wherein:

dt represents the on-time of the circuit breaker solid-state switch 26and, thus, with the corresponding off-time, defines the modulation dutycycle. As the pulses build the voltage Vc in the cable capacitance, thedifference (60 kVdc−Vc) diminishes, which increases dt and, thus, theduty cycle. When Vc reaches 60 kVdc, the difference (60 kVdc−Vc) equalszero and dt goes to infinity, which means that the solid-state switch 26is continuously turned on.

Example 5

The galvanically isolated buck DC/DC converter 12 allows for the motoroutput 14B of the DC to AC voltage source inverter 14 to have one of itsthree phases grounded. The DC/DC converter 12 is isolated and reducesthe HVDC coming from the source to a DC voltage level that is compatiblewith the motor insulation rating. This reduced voltage is fed into theinput DC bus 14A of the DC/AC voltage source inverter 14 whose output14B feeds the AC transmission line 16 and subsequently the AC motor 18.The galvanic isolation reduces the effective zero sequence currents thatmay flow to the three-phase cable 16 and the AC motor 18. This isolationallows shorting to ground of one of the motor phases with no operationalinterruption. The DC/AC voltage source inverter 14 is an activeconverter and, thus, the output 14B thereof is protected against shortcircuit faults.

The galvanically isolated DC/DC buck converter 12 in the same enclosure20 as the DC/AC voltage source inverter 14 allows for the transmissionof power at high voltage up to the input 14A of the voltage sourceinverter 14, which reduces the current levels and consequently thevoltage transients due to current changes in the HVDC transmission lineof the HVDC cable 10 and better utilization of the cable conductor crosssection. Also, a fault current generated due to a short circuit in theinput 14A of the voltage source inverter 14 will be contained by theDC/DC buck converter 12.

The high power AC motor 18 is designed for medium voltage to reduce thecopper cross section of its windings and of the corresponding supplycable 16. The “buck” aspect of the galvanically isolated DC/DC buckconverter 12 reduces the high direct current voltage from thecorresponding HVDC cable 10 to a medium direct current voltage.Typically, for subsea applications, the AC motors 18 are rated, forexample and without limitation, for 4160 V or 6600 V input. Theinsulation rating for a 6600 V motor is 20 kVDC or 14,200 VAC_(RMS). Ifpower is transmitted from a surface platform (see the AC/DC converter 4of FIG. 5) to the motor 18 subsea at about 60 kVDC, then this voltage isthree times higher than the motor's insulation voltage rating.Therefore, at some point in the transmission line, the 60 kVDC has to bereduced to well below 20 kVDC. For the inverter 14 to produce a 6600 VACoutput, its input voltage needs to be around 10 kVDC. Hence, the DC/DCconverter 12 reduces the transmitted 60 kVDC, in this example, to 10kVDC.

Subsea cables are relatively expensive, such as about $1000 per meternot counting the installation cost. The largest cables for subseaapplications would be ideally limited to around 240 square millimetersdue to sheer size and weight which affect the cost and difficulty ofinstallation. This means that the electric current is limited by thecopper cross section. For 240 square millimeters, the maximum payloadcurrent is between 400 A to 500 A depending on the top side and watertemperature conditions.

In order to transmit power effectively, a high voltage is needed asclose to the load 18 as possible, in order to reduce the amount ofcurrent in the transmission line and thus reduce the conductor crosssection, which in the subsea case, has a limit due to installationrestrictions. This is provided by the inclusion of the DC/DC buckconverter 12 with the inverter 14 whose output 14B feeds the AC motor18. In the above example, the 60 kVDC is transmitted all the way to thepoint of delivery and the system 2 can benefit from the lower current upto that point. Continuing to apply this concept to the above example,with a 450 A maximum cable current and 60 kVDC, the transmission linecan carry 27 megawatts. With the same 450 A limitation and 10 kVDC, themaximum power transmitted is 4.5 megawatt.

The disclosed “in the same box” configuration of the DC/DC buckconverter 12, the inverter 14 and the enclosure 20 reduces currentlevels and consequently voltage transients due to current changes in thetransmission line of the HVDC cable 10 and provides better utilizationof the cable conductor cross section. Better utilization of the cableconductor cross section was explained, above. The reduction of voltagetransients is a consequence of the reduction of current magnitude. Theformula for voltage transients in a transmission line can be simplifiedto obtain:Vtrans=L*di/dtwherein:

Vtrans is the peak voltage transient which goes above the DCtransmission voltage;

L is the inductance of the transmission line; and

di/dt is the current transient which is higher in the presence ofsolid-state switching devices switching loads on or off.

Therefore, for the same switching time, dt, a smaller current magnitude,di, will produce a smaller transient voltage.

The galvanically isolated DC/DC buck converter 12 allows for the outputto the AC motor 18 to be grounded in one of the phases. The systemgrounding is complex when it comes to DC transmission. The generators ona surface platform (e.g., FIG. 5) will be generally high impedancegrounded. The output of the AC/DC converter 14 is also high impedancegrounded via its neutral point. When using a DC/DC converter 12 that isisolated from the source on the platform, it means that the invertercircuit connected to its output 12B is electrically floating withreference to the source. Therefore, if any one of the inverter's outputterminals 14B is connected to ground, then there is no ground currentthat flows in the source.

If there is a short circuit operatively associated with the DC input 14Aof the corresponding voltage source inverter 14 (e.g., withoutlimitation, in the inverter components (not shown)), then the powersemiconductor switches (not shown) of the galvanically isolated DC/DCbuck converter 12 are turned off to shut down the converter 12, thus,protecting the inverter 14 from excessive fault energy.

Example 6

The voltage source inverter 14 inputs from the DC input 14A and outputsAC from the output 14B to the AC motor 18. Due to the possibility ofrelatively long electrical connections between the inverter output 14Band the AC motor 18, there can be a suitable filter (not shown) tominimize common mode and harmonic currents. The inverter 14 protects thethree-phase transmission lines 16 and the motor windings (not shown) incase of a short circuit fault. The inverter output 14B has a filter (notshown) to suppress the pulse width modulation transients allowing for arelatively long transmission line cable 16 to the AC motor 18. Theinverter 14 employs a selective harmonic elimination modulation methodto minimize the filter size.

A fault current generated due to a short circuit in the transmissionlines 16 or the AC motor 18 will be contained by the inverter 14.

The voltage source inverter 14 has a relatively large capacitor (notshown) connected between the positive and the negative terminals of itsinput DC bus 14A. In contrast, a current source inverter (not shown)does not have such as capacitor, but does have a relatively largeinductor (not shown) in series with its DC bus positive and/or negativeterminals (not shown) of its input DC bus.

The distribution system 7 is divided into sections that are protected bydifferent elements in the circuit. The AC motor 18 is protected by theinverter 14. If there is a short circuit in the three-phase transmissionlines 16 between the inverter 14 and the motor 18 or in the motor 18itself, then the inverter semiconductor switches (not shown) are turnedoff to stop the fault current that is detected by the inverter controlcircuit (not shown).

The alternating current output 14B of the voltage source inverter 14 canbe a low alternating current voltage, a medium alternating currentvoltage, or a high alternating current voltage.

Example 7

The three-phase transmission lines 16 can employ low, medium or highvoltage AC.

Example 8

The AC motor 18 can be a low, medium or high voltage AC motor, such as athree-phase AC motor.

Example 9

The enclosure 20 is preferably compensated for subsea pressure. Forexample and without limitation, U.S. Pat. No. 6,822,866 discloses apower conversion system that is void of air by the vacuuming andimmersion of power conversion system components in a dielectric gel,oil, gas or in vacuum. This permits the high voltage circuit to becomemuch smaller than it would be in air. To build a pressure compensatedpower conversion system, its components are immersed in a fluid that:(1) fills all gaps and voids in the converter structure in order toallow the pressure in the enclosure 20 to be equalized with the externalpressure; (2) is dielectric in nature and inert to prevent chemicalcorrosion of components immersed therein; and (3) transports heat energygenerated in the DC/DC converter components to the walls (not shown) ofthe enclosure 20.

Example 10

The disclosed concept permits the cable size of the three-phasetransmission lines 16 to be relatively smaller and to get increasinglysmaller as it gets closer to the AC motor 18 due to the decreasing seawater temperature as the cable goes deeper. One umbilical cable is for20,000 MW (e.g., maximum cable size has to do with its temperaturerating and the limitations imposed by the I-tube (e.g., withoutlimitation, a straight vertical tube that is typically 220 feet long,encases the power cable (or “umbilical”), is physically attached to theplatform structure, and protects the cable against sea-induced motions),which supports and holds the cable that leaves the oil platform at sealevel as it goes down into the sea bed; there is a length of cable thatthe I-tube grabs and thus constrains the cable cooling and thus requiresthe worst case conductor cross section; as the transmission lineincreases in the subsea region, the water temperature drops dramaticallyand the cable could have its conductor cross section reduced from agiven splice point). This permits transmission of DC power until a fewmeters from the drive/motor system at the voltage source inverter 14.The voltage drop due to relatively long cable length and load powervariation is compensated by the AC/DC converter 4 and the DC/DCconverter 12 regulates the DC bus voltage of the inverter 14 to providefull 6.6 kV to the AC motor 18 regardless of the cable length or loadvariation. The voltage source inverter 14 to AC motor 18 cable distancecan be reduced to less than 150 feet. Performance and control areimproved and there is no need for expensive filters.

Example 11

The disclosed concept can employ a surface or sea-bed installed AC to DC(typically 10 kVDC to 240 kVDC scalable) two-wire (+, −configured) powerconversion assembly fed by a single umbilical cable to a HVDC switchgearassembly comprised of one or multiple solid-state protected andcontrolled HVDC circuit breakers 8 in a pressure compensated enclosure(not shown but see Example 9) to withstand, for example, a minimum of300 bar of pressure and 3 kM of sea water depth.

Example 12

The individual sea-bed switchgear breakers 8 or single group mountedswitchgear breakers 8 could feed various AC or DC loads, such as theexample AC motors 18, on the sea-bed including the voltage sourceinverter 14 up to and exceeding 13.8 kVAC output voltage.

Example 13

FIGS. 6A-6B show an example distribution system 7 according to thedisclosed concept, as powered by the AC/DC converter 4 and the HVDCcable 6, including the subsea switch gear 8, plural cables 10, pluraldrives each formed by the DC/DC buck converter 12 and the voltage sourceinverter 14, plural cables 16 and plural AC motors 18. Exampleelectrical and cable parameters are also shown. Due to the examplesystem disclosed here, the transmission and distribution cables neverconduct a current higher than the 450 A limit.

Example 14

FIGS. 7 and 8 show differences between a prior system 2′ and anon-limiting example of the disclosed system 2, except simplified toremove the HVDC circuit breaker 8. The case in FIG. 7 shows theconsequence of reducing the DC voltage midway and the other case in FIG.8 shows the advantages of having the DC/DC converter 12 in the sameenclosure 20 (FIG. 1) as the inverter 14. The example cable parametersaccurately reflect real world parameters. In both cases, the AC/DCconverter 4 transmits 132 kVdc and 401 A via a 270 mile cable in FIG. 7and a 309 mile cable in FIG. 8. Due to the resistive losses in the cablein FIG. 7, the input voltage at the input of the DC/DC converter 12 is97.9 kV while in FIG. 8 it is 92.9 kVdc. By transmitting the high DCvoltage on the HVDC cable 10 up to the drive enclosure 20 in FIG. 8,which includes the buck DC/DC converter 12 (which reduces 92.9 kVDC to11 kVDC), this avoids any substantial length of cable 13′ (FIG. 7)carrying a current of 3480 Adc and needing a ten times higher crosssection than the 240 sq. mm. HVDC cable 10 in the example. Instead, therelatively short conductor bus (e.g., a few feet of length) 13 (FIG. 8)carries 3,480 ADC at 11 kVDC to transmit the same amount of load power.

FIGS. 9-12 show modular distribution systems 100,200,300,400,respectively.

Example 15

FIG. 9 shows a supply cable 102 (e.g., such as HVDC cable 6 of FIG. 1)electrically connected to a line (e.g., supply) plug 104 of a singlecircuit breaker enclosure 106 having three example branch circuitbreakers 108,110,112, each of which has a load plug 114,116,118,respectively. The example branch circuit breakers 108,110,112 are HVDCcircuit breakers, the same as or similar to the HVDC circuit breaker 8of FIG. 1, and are enclosed by the example single enclosure 106. Thesingle line plug 104 is externally electrically connected to theopposite second end 120 of the HVDC cable 102 and is internallyelectrically connected to a first input portion 124 of the HVDC circuitbreakers 108,110,112. Each of the load plugs 114,116,118 is externallyelectrically connected to a first input end 126 of a corresponding HVDCcable 128.

Example 16

FIG. 10 shows the supply cable 202 electrically connected to a line(e.g., supply) plug 204 of a distribution module 206 having an input 207and three example output plugs 208,210,212, each of which engages aseparate HVDC branch circuit breaker 214,216,218, each of which has aload plug 220 and is enclosed by a corresponding enclosure 215,217,219,respectively.

FIG. 11 is similar to FIG. 10 except that the distribution module 206′is interconnected with the HVDC branch circuit breakers 214,216,218 bythree external cables 302,304,306, respectively. The distribution module206′ has an input 308 electrically connected to the opposite second end310 of the supply cable 202 and a plurality of outputs 312,314,316. Eachof the outputs 312,314,316 is electrically connected to the inputportion 318 of a corresponding one of the HVDC circuit breakers214,216,218.

Example 17

FIG. 12 shows a supply cable 402 electrically connected to a line (e.g.,supply) plug 410 of a circuit breaker enclosure 406 having one branchcircuit breaker 408 including the line plug 410, a load plug 412 and adaisy chain plug 414. Two other circuit breaker enclosures 416,418, eachhaving one branch circuit breaker 420 including a line plug 422, a loadplug 424 and a daisy chain plug 426, are interconnected with the firstcircuit breaker enclosure 406 by daisy chain cables 428 electricallyconnected between the daisy chain plug 414 or 426 of a prior circuitbreaker enclosure 406,416 and the line plug 422 of another circuitbreaker enclosure 416,418.

The line plug 410 of the enclosure 406 is externally electricallyconnected to the opposite second end 404 of the HVDC cable 402 andinternally electrically connected to the plug 414 and the input portion408A of the HVDC circuit breaker 408. For the HVDC circuit breakers 420,the jumper cables 428 electrically connect the plugs 414 and 422 or 426and 422. Each of the load plugs 412,424 is externally electricallyconnected to the first end 430 of a corresponding HVDC cable 432.

While specific embodiments of the disclosed concept have been describedin detail, it will be appreciated by those skilled in the art thatvarious modifications and alternatives to those details could bedeveloped in light of the overall teachings of the disclosure.Accordingly, the particular arrangements disclosed are meant to beillustrative only and not limiting as to the scope of the disclosedconcept which is to be given the full breadth of the claims appended andany and all equivalents thereof.

What is claimed is:
 1. A direct current to alternating current invertersub-system for a high voltage direct current distribution system, saiddirect current to alternating current inverter sub-system comprising: anenclosure; a direct current to direct current galvanically isolated buckconverter including a direct current input electrically connectable to ahigh voltage direct current cable and a direct current output, whereinthe direct current to direct current galvanically isolated buckconverter is structured to provide galvanic isolation between the directcurrent input and the high voltage direct current cable to avoid groundcurrents in the high voltage direct current cable; and a direct currentto alternating current voltage source inverter including a directcurrent input electrically connected to the direct current output ofsaid direct current to direct current galvanically isolated buckconverter and an alternating current output electrically connectable toan alternating current transmission line, wherein said direct current toalternating current voltage source inverter is mounted in said enclosurewith said direct current to direct current galvanically isolated buckconverter, in order that the direct current output of said directcurrent to direct current galvanically isolated buck converter isdirectly electrically connected within the enclosure to the directcurrent input of said direct current to alternating current voltagesource inverter.
 2. The direct current to alternating current invertersub-system of claim 1 wherein said enclosure is compensated for subseapressure.
 3. The direct current to alternating current invertersub-system of claim 1 wherein said direct current to direct currentgalvanically isolated buck converter is structured to shut downresponsive to a short circuit condition operatively associated with thedirect current input of said direct current to alternating currentvoltage source inverter.
 4. The direct current to alternating currentinverter sub-system of claim 1 wherein said direct current to directcurrent galvanically isolated buck converter is structured to reduce ahigh direct current voltage from the high voltage direct current cableto a medium direct current voltage.
 5. A circuit interrupter for a powercircuit of a high voltage direct current distribution system, saidcircuit interrupter comprising: a first terminal; a second terminal; anelectromechanical isolation switch; a solid-state switch electricallyconnected in series with said electromechanical isolation switch betweensaid first and second terminals; and a controller cooperating with saidsolid-state switch and said electromechanical isolation switch to open,close and trip open said power circuit, said controller being structuredto repetitively turn on and turn off said solid-state switch a pluralityof times when said electromechanical isolation switch is closed, inorder to control charging of said power circuit from zero volts to ahigh direct current voltage, wherein said controller further comprises atrip mechanism structured to detect a fault downstream of said secondterminal responsive to a failure to charge said power circuit, whereinsaid trip mechanism is structured to apply a predetermined current pulseto said power circuit, detect a corresponding predetermined voltageincrease of a voltage of said power circuit, determine whether, within acertain time period, the voltage of said power circuit has decayed,responsive to determining that the voltage of said power circuit hasdecayed, determining that the fault downstream of said second terminalis present, and responsive to determining that the voltage of said powercircuit has not decayed, determining that the fault downstream of saidsecond terminal is not present.
 6. The circuit interrupter of claim 5wherein when both of said electromechanical isolation switch and saidsolid-state switch are closed, said second terminal charges said powercircuit to or toward the high direct current voltage from said firstterminal.
 7. The circuit interrupter of claim 6 wherein said controllercomprises a modulation element controlling said charging of said powercircuit, said modulation element being structured to ramp a duty cycleof said solid-state switch being on from zero to one hundred percent. 8.The circuit interrupter of claim 5 wherein said failure to charge iscaused by a short circuit or an insulation failure of a high voltagedirect current cable of said power circuit.